Techniques for requesting data associated with a cache line in symmetric multiprocessor systems

ABSTRACT

A technique for operating a data processing system includes transitioning, by a cache, to a highest point of coherency (HPC) for a cache line in a required state without receiving data for one or more segments of the cache line that are needed. The cache issues a command to a lowest point of coherency (LPC) that requests data for the one or more segments of the cache line that were not received and are needed. The cache receives the data for the one or more segments of the cache line from the LPC that were not previously received and were needed.

BACKGROUND

The present disclosure relates in general to data processing systems and, in particular, to techniques for requesting data associated with a cache line in symmetric multiprocessor systems.

Traditionally, symmetric multiprocessor (SMP) systems, such as server computer systems, have included multiple processing units all coupled to a system interconnect, which has included one or more address, data, and control buses. Coupled to the system interconnect was a system memory, which represented the lowest level of volatile memory in the multiprocessor computer system and which was generally accessible for read and write access by all processing units. In order to reduce access latency to instructions and data residing in the system memory, each processing unit was typically further supported by a respective multi-level cache hierarchy, the lower level(s) of which may be shared by one or more processor cores.

BRIEF SUMMARY

A technique for operating a data processing system includes transitioning, by a cache, to a highest point of coherency (HPC) for a cache line in a required state without receiving data for one or more segments of the cache line that are needed. The cache issues a command to a lowest point of coherency (LPC) that requests data for the one or more segments of the cache line that were not received and are needed. The cache receives the data for the one or more segments of the cache line from the LPC that were not previously received and were needed.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a high level block diagram of an exemplary processing unit according to one embodiment of the present disclosure;

FIG. 2 is a high level block diagram of an exemplary data processing system according to one embodiment of the present disclosure;

FIG. 3 is a time-space diagram of an exemplary operation including a request phase, a partial response phase, and a combined response phase;

FIG. 4 is a time-space diagram of an exemplary operation of system-wide scope within the data processing system of FIG. 2;

FIG. 5 is a time-space diagram of an exemplary operation of node-only scope within the data processing system of FIG. 2;

FIG. 6 is a time-space diagram of an exemplary operation, illustrating the timing constraints of an arbitrary data processing system topology;

FIG. 7 is an exemplary embodiment of a partial response field for a write request that is included within the link information allocation;

FIG. 8 is a block diagram illustrating a portion of the interconnect logic of FIG. 1 utilized in the request phase of an operation;

FIG. 9 is a more detailed block diagram of the local hub address launch buffer of FIG. 8;

FIG. 10 is a more detailed block diagram of the tag FIFO queues of FIG. 8;

FIGS. 11 and 12 are more detailed block diagrams of the local hub partial response FIFO queue and remote hub partial response FIFO queue of FIG. 8, respectively;

FIG. 13 is a flowchart that depicts exemplary operations performed by a master of a level two (L2) cache in response to receiving a transaction; and

FIG. 14 is a more detailed block diagram of an exemplary snooping component of the data processing system of FIG. 2.

DETAILED DESCRIPTION

As used herein, a lowest point of coherency (LPC) refers to a device of a data processing system that serves as a repository for a memory block. For a typical request in a data processing system, an LPC corresponds to a memory controller for system (main) memory that holds a referenced memory block. As is also used herein, a highest point of coherency (HPC) is a uniquely identified device that caches a true image of a memory block (which may or may not be consistent with a corresponding memory block at an LPC) and has the authority to grant or deny a request to modify the memory block. An HPC may also provide a copy of a memory block to a requestor in response to, for example, a command. In the absence of an HPC for a memory block, an LPC holds a true image of the memory block and has authority to grant or deny requests to generate an additional cached copy of the memory block.

In conventional data processing systems, access to data has typically required movement of a full (e.g., a 128-byte) cache line. In data processing systems that have proposed or implemented segmented cache lines, access to data may only require movement of a cache line segment (e.g., a 64-byte segment of a 128-byte cache line). Due to various reasons, there may be times when a desired segment of a cache line segment is not received by an HPC of the cache line. According to aspects of the present disclosure, techniques are disclosed in which an HPC of a cache line may request one or more segments of the cache line from a lowest point of coherency (LPC), e.g., a memory controller. According to one or more aspects of the present disclosure, an HPC of a cache line accesses one or more segments of the cache line from an LPC by issuing a highest point of coherency read (hpc_read) command. The hpc_read command allows an issuing master of a cache, e.g., an L2 cache, that is an HPC of a cache line to request data associated with the cache line when ownership of the cache line has transitioned to the cache. When issued by an HPC of a cache line, the hpc_read command facilitates accessing data from the LPC by the HPC of the cache line.

In various instances, ownership of a cache line may be obtained without associated data being provided. As one example, ownership of a non-critical cache line segment may be obtained through cache intervention. As another example, a data cache block flush and claim (dcbfc) command may be issued by a master of an L2 cache when ownership of a cache line is desired and the entire cache line is expected to be replaced. In any case, once ownership of a cache line is established, a master of an L2 cache, as HPC of the cache line, can obtain data associated with the cache line (either one or more segments of the cache line or the entire cache line, as needed) by issuing an hpc_read command to an LPC for the cache line. Given that the hpc_read command does not cause any coherent ownership hand-off, the hpc_read command is not required to be snooped by any L2 cache snoopers and is only snooped by LPC snoopers (which may be limited by scope).

As one example, an hpc_read command may take the following form:

HPC Read AD Ln, Nn, Rn, G, Vg hpc_read ‘010 1111’ ‘s000 0000’ The hpc_read command has an opcode field (represented by the mnemonic ‘hpc_read’) that specifies the command is an hpc_read command, a primary encode (that specifies it is an AD class command with an address (A) field that specifies an address of a targeted LPC and an expected data (D) tenure field) and a secondary encode that includes an ‘s’ field that specifies if an entire cache line or an identified segment of the cache line is to be returned to an issuing master by the LPC, as well as a command scope (i.e., local node (Ln), Near node (Nn), remote node (Rn), group (G), and vectored group (Vg)).

As used herein, Ln scope refers to a broadcast scope that is constrained to the boundaries of a node in which the master issuing the command is located (master node). Nn scope, as used herein, refers to a broadcast scope that is constrained to the boundaries of a node in which the master issuing the command is located (master node) and the boundaries of a node which is specified as the home node of the address specified by the command (target node). In Nn scope, the target node is located within a same group as the master node. As used herein, Rn scope refers to a broadcast scope that is constrained to the boundaries of a node in which a master issuing the command is located (master node) and the boundaries of a node which is specified as the home node of the address specified by the command (target node). In Rn scope, the target node is not located within a same group as the master node. G scope, as used herein, refers to the broadcast scope that is constrained to the boundaries of the group in which a master issuing the command is located. As used herein, Vg scope refers to a broadcast scope that is constrained to the boundaries of the master's group and all the groups specified by the master's specified scope target.

The secondary encode specifies the ‘s’ field indicating the amount of data transferred. As one example, when S=0 a full cache line transfer of 128-bytes is indicated and when S=1 a 64-byte segment transfer is indicated (in this case the address specifies which segment is returned). In one or more embodiments, only LPCs within a designated scope snoop the hpc_read command. In one or more embodiments, the LPC owning the address specified by the command issues an LPC acknowledgment (lpc_ack) response to the hpc_read command. In at least one embodiment, when the LPC owning the address is unable to service the hpc_read command, the LPC issues a retry LPC (rty_lpc) response. In various embodiments, the hpc_read command does not require any epsilon (c) window, as there is no ownership hand-off, i.e., the master that issues the hpc_read command is already the owner of the cache line and is only obtaining data associated with the cache line.

In general, the hpc_read command provides data to a master of an L2 cache that already has ownership of a cache line in a required state but does not have all (or any) data associated with the cache line. In at least one embodiment, an LPC treats the hpc_read command as a high service priority command. The hpc_read command is not snooped by snoopers of L2 caches, as only an LPC may complete the operation. As previously mentioned, a master of an L2 cache may issue the hpc_read command to obtain a missing segment or segments of a cache line owned by the L2 cache, e.g., in a modified state. In one or more embodiments, a master of an L2 cache that is an HPC may use the hpc_read command to obtain data for a cache line in an invalidated I_(hpc) state (i.e., L2 cache is the HPC of the cache line, but the data is held in the invalidated ‘I’ state). It should be appreciated that a master of an L2 cache that is an HPC for a cache line in the invalidated I_(hpc) state does not hold a copy of the cache line and cannot intervene data for the cache line. As one example, an I_(hpc) state may be created by a master when data cache block flush and claim (dcbfc) command is successfully completed, as the most current version of the cache line is maintained by an associated LPC due to the actions taken when executing the dcbfc command.

As another example, when a load and reserve instruction hits an L2 cache and the L2 cache only holds a single segment of the cache line, a master in the L2 cache may issue an hpc_read command to obtain one or more other segments of the cache line. As yet another example, when a load and reserve instruction misses the L2 cache and hits its level 3 (L3) cache, a segment held by the L3 cache is sent to the L2 cache and a master in the L2 cache may issue an hpc_read to obtain one or more other segments of the cache line.

As previously mentioned, the hpc_read command is only snooped by LPCs. The LPC issues an lpc_ack response unconditionally when an address identified by the hpc_read command is owned by the LPC. As mentioned above, an LPC issues a rty_lpc response when the LPC is unable to service the command. In various embodiments, an LPC operation group for the hpc read command is non-blocking in the LPC. In one or more embodiments, a master of an L2 cache is not required to fetch a full cache line using the hpc_read command if a desired segment is provided, regardless of the source (HPC or LPC) of the desired segment. The hpc_read command with s=1 can be used, for example, to handle cases where a cache intervention provides only a segment of a cache line and the LPC does not provide the remaining segment.

In various embodiments, an HPC that issues using an hpc_read command cannot be blocked from accessing data for a cache line, as the HPC is already protecting the cache line. In at least one embodiment, the use of the hpc_read command to retrieve data for a cache line can only be issued by a master holding the cache line in a modified (Mx) state. When a master of an L2 cache only receives a segment of a cache line the master may be required (as determined by a combined response) to obtain the entire cache line using the hpc_read command. If a segment obtained is not a desired segment then the master may obtain the desired segment using the hpc_read command.

A broadcast command originates from within a processing unit, which selects a required broadcast scope for the command to target a particular chip, a particular group of chips, or a system. In general, a command may be issued at a system scope or a scope that is some subset of the system. As used herein, a ‘system’ is considered to be a collection of processing units and memory whose memory address range is shared (flat address space) and is defined as a collection of one or more ‘groups’. Each ‘group’ may include one or more ‘chips’. A ‘chip’ is a collection of one or more ‘units’. A ‘unit’ is a collection of one or more ‘agents’ that interact with a communication bus (e.g., the PowerBus) through control and data interfaces. While the discussion herein focuses on an L2 cache as being the HPC for a cache line, it is contemplated that the techniques disclosed herein may also be applicable to different level caches that are capable of becoming the HPC for a cache line.

With reference now to the figures and, in particular, with reference to FIG. 1, there is illustrated a high level block diagram of an exemplary embodiment of a processing unit 100 in accordance with the present invention. In the depicted embodiment, processing unit 100 is a single integrated circuit (chip) including multiple (e.g., eight) processor cores 102 a-102 h for independently processing instructions and data. Each processor core 102 includes at least an instruction sequencing unit (ISU) 104 for fetching and ordering instructions for execution and one or more execution units 106 for executing instructions. The instructions executed by execution units 106 may include, for example, fixed and floating point arithmetic instructions, logical instructions, and instructions that request read and write access to a memory block.

The operation of each processor core 102 is supported by a multi-level volatile memory hierarchy having at its lowest level one or more shared system memories 132 (only one of which is shown in FIG. 1) and, at its upper levels, one or more levels of cache memory. As depicted, processing unit 100 includes an integrated memory controller (IMC) 124 that controls read and write access to a system memory 132 in response to requests received from processor cores 102 and operations snooped on an interconnect fabric (described below) by snoopers 126.

In the illustrative embodiment, the cache memory hierarchy of processing unit 100 includes a store-through level one (L1) cache 108 within each processor core 102 and a level two (L2) cache 110 shared by all processor cores 102 of the processing unit 100. L2 cache 110 includes an L2 array and directory 114, masters 112, and snoopers 116. Masters 112 initiate transactions on the interconnect fabric and access L2 array and directory 114 in response to memory access (and other) requests received from the associated processor cores 102. Snoopers 116 detect operations on the interconnect fabric, provide appropriate responses, and perform any accesses to L2 array and directory 114 required by the operations. Although the illustrated cache hierarchy includes only two levels of cache, those skilled in the art will appreciate that alternative embodiments may include additional levels (L3, L4, etc.) of on-chip or off-chip in-line or lookaside cache, which may be fully inclusive, partially inclusive, or non-inclusive of the contents the upper levels of cache.

As further shown in FIG. 1, processing unit 100 includes integrated interconnect logic 120 by which processing unit 100 may be coupled to the interconnect fabric as part of a larger data processing system. In the depicted embodiment, interconnect logic 120 supports an arbitrary number t1 of “first tier” interconnect links, which in this case include in-bound and out-bound X, Y, and Z links. Interconnect logic 120 further supports an arbitrary number t2 of second tier links, designated in FIG. 1 as in-bound and out-bound A and B links. With these first and second tier links, each processing unit 100 may be coupled for bi-directional communication to up to t1/2+t2/2 (in this case, five) other processing units 100. Interconnect logic 120 includes request logic 121 a, partial response logic 121 b, combined response logic 121 c, and data logic 121 d for processing and forwarding information during different phases of operations. In addition, interconnect logic 120 includes a configuration register 123 including a plurality of mode bits utilized to configure processing unit 100. As further described below, these mode bits preferably include: (1) a first set of one or more mode bits that selects a desired link information allocation for the first and second tier links; (2) a second set of one or more mode bits that specify which of the first and second tier links of the processing unit 100 are connected to other processing units 100; (3) a third set of one or more mode bits that determines a programmable duration of a protection window extension; (4) a fourth set of one or more mode bits that predictively selects a scope of broadcast for operations initiated by the processing unit 100 on an operation-by-operation basis from, for example, a node-only broadcast scope, a system-wide scope, or other scope; and (5) a fifth set of one or more mode bits indicating a group to which processing unit 100 belongs.

Each processing unit 100 further includes an instance of response logic 122, which implements a portion of a distributed coherency signaling mechanism that maintains cache coherency between the cache hierarchy of processing unit 100 and those of other processing units 100. Finally, each processing unit 100 includes an integrated I/O (input/output) controller 128 supporting the attachment of one or more I/O devices, such as I/O device 130. I/O controller 128 may issue operations and receive data on the X, Y, Z, A, and B links in response to requests by I/O device 130.

Referring now to FIG. 2, there is depicted a block diagram of an exemplary embodiment of a data processing system 200 formed of multiple processing units 100 in accordance with the present disclosure. As shown, data processing system 200 includes eight processing nodes (groups) 202 a 0-202 d 0 and 202 a 1-202 d 1, which in the depicted embodiment, are each realized as a multi-chip module (MCM) comprising a package containing four processing units 100. The processing units 100 within each processing node 202 are coupled for point-to-point communication by the processing units' X, Y, and Z links, as shown. Each processing unit 100 may be further coupled to processing units 100 in two different processing nodes 202 for point-to-point communication by the processing units' A and B links. Although illustrated in FIG. 2 with a double-headed arrow, it should be understood that each pair of X, Y, Z, A, and B links may be implemented as two uni-directional links, rather than as a bi-directional link.

General expressions for forming the topology shown in FIG. 2 can be given as follows:

Node[ I ][ K ].chip[ J ].link[ K ] connects to Node[ J ][ K ].chip[ I ].link[ K ], for all I ≠ J; and Node[ I ][ K ].chip[ I ].link[ K ] connects to Node[ I ][ not K ].chip[ I ].link[ not K ]; and Node[ I ][ K ].chip[ I ].link[ not K] connects either to:    (1) Nothing in reserved for future expansion; or    (2) Node[ extra ][ not K ].chip[ I ].link[ K ], in case in which all    links are fully utilized (i.e., nine 8-way nodes forming a 72-way    system); and where I and J belong to the set {a, b, c, d} and K    belongs to the set {A,B}.

Of course, alternative expressions can be defined to form other functionally equivalent topologies. Moreover, it should be appreciated that the depicted topology is representative but not exhaustive of data processing system topologies embodying techniques of the present disclosure and that other topologies are possible. In such alternative topologies, for example, the number of first tier and second tier links coupled to each processing unit 100 can be an arbitrary number, and the number of processing nodes 202 within each tier (i.e., I) need not equal the number of processing units 100 per processing node 100 (i.e., J).

Even though fully connected in the manner shown in FIG. 2, all processing nodes 202 need not communicate each operation to all other processing nodes 202. In particular, as noted above, processing units 100 may broadcast operations with a scope limited to their processing node (group) 202 or with a larger scope, such as multiple groups or a system-wide scope including all processing nodes 202.

As shown in FIG. 14, an exemplary snooping device 1400 within data processing system 200, for example, snoopers 116 of L2 (or lower level) cache or snoopers 126 of an IMC 124, may include one or more base address registers (BARs) 1402 identifying one or more regions of the real address space containing real addresses for which snooping device 1400 is responsible. Snooping device 1400 may optionally further include hash logic 1404 that performs a hash function on real addresses falling within the region(s) of real address space identified by BAR 1902 to further qualify whether or not the snooping device 1400 is responsible for the addresses. Finally, snooping device 1400 includes a number of snoopers 1406 a-1406 m that access resource 1410 (e.g., L2 cache array and directory 114 or system memory 132) in response to snooped requests specifying request addresses qualified by BAR 1402 and hash logic 1404.

As shown, resource 1410 may have a banked structure including multiple banks 1412 a-1412 n each associated with a respective set of real addresses. As is known to those skilled in the art, such banked designs are often employed to support a higher arrival rate of requests for resource 1410 by effectively subdividing resource 1410 into multiple independently accessible resources. In this manner, even if the operating frequency of snooping device 1400 and/or resource 1410 are such that snooping device 1400 cannot service requests to access resource 1410 as fast as the maximum arrival rate of such requests, snooping device 1400 can service such requests without retry as long as the number of requests received for any bank 1412 within a given time interval does not exceed the number of requests that can be serviced by that bank 1412 within that time interval.

Those skilled in the art will appreciate that SMP data processing system 100 can include many additional unillustrated components, such as interconnect bridges, non-volatile storage, ports for connection to networks or attached devices, etc. Because such additional components are not necessary for an understanding of the present invention, they are not illustrated in FIG. 2 discussed further herein.

Referring now to FIG. 3, there is depicted a time-space diagram of an exemplary operation on the interconnect fabric of data processing system 200 of FIG. 2. The operation begins when a master 300 (e.g., a master 112 of an L2 cache 110 or a master within an I/O controller 128) issues a request 302 on the interconnect fabric. Request 302 preferably includes at least a transaction type indicating a type of desired access and a resource identifier (e.g., real address) indicating a resource to be accessed by the request. Common types of requests preferably include those set forth below in Table I.

TABLE I Request Description READ Requests a copy of the image of a memory block for query purposes RWITM (Read-With- Requests a unique copy of the image of a memory block with the intent Intent-To-Modify) to update (modify) it and requires destruction of other copies, if any DCLAIM (Data Requests authority to promote an existing query-only copy of memory Claim) block to a unique copy with the intent to update (modify) it and requires destruction of other copies, if any DCBZ (Data Cache Requests authority to create a new unique copy of a memory block Block Zero) without regard to its present state and subsequently modify its contents; requires destruction of other copies, if any CASTOUT Copies the image of a memory block from a higher level of memory to a lower level of memory in preparation for the destruction of the higher level copy WRITE Requests authority to create a new unique copy of a memory block without regard to its present state and immediately copy the image of the memory block from a higher level memory to a lower level memory in preparation for the destruction of the higher level copy PARTIAL WRITE Requests authority to create a new unique copy of a partial memory block without regard to its present state and immediately copy the image of the partial memory block from a higher level memory to a lower level memory in preparation for the destruction of the higher level copy

Request 302 is received by snoopers 304, for example, snoopers 116 of L2 caches 110 and snoopers 126 of IMCs 124, distributed throughout data processing system 200. In general, with some exceptions, snoopers 116 in the same L2 cache 110 as the master 112 of request 302 do not snoop request 302 (i.e., there is generally no self-snooping) because a request 302 is transmitted on the interconnect fabric only if the request 302 cannot be serviced internally by a processing unit 100. Snoopers 304 that receive and process requests 302 each provide a respective partial response 306 representing the response of at least that snooper 304 to request 302. A snooper 126 within an IMC 124 determines the partial response 306 to provide based, for example, upon whether the snooper 126 is responsible for the request address and whether it has resources available to service the request. A snooper 116 of an L2 cache 110 may determine its partial response 306 based on, for example, the availability of its L2 cache directory 114, the availability of a snoop logic instance within snooper 116 to handle the request, and the coherency state associated with the request address in L2 cache directory 114.

The partial responses 306 of snoopers 304 are logically combined either in stages or all at once by one or more instances of response logic 122 to determine a combined response (CR) 310 to request 302. In one preferred embodiment, which will be assumed hereinafter, the instance of response logic 122 responsible for generating combined response 310 is located in the processing unit 100 containing the master 300 that issued request 302. Response logic 122 provides combined response 310 to master 300 and snoopers 304 via the interconnect fabric to indicate the response (e.g., success, failure, retry, etc.) to request 302. If the CR 310 indicates success of request 302, CR 310 may indicate, for example, a data source for a requested memory block, a cache state in which the requested memory block is to be cached by master 300, and whether “cleanup” operations invalidating the requested memory block in one or more L2 caches 110 are required.

In response to receipt of combined response 310, one or more of master 300 and snoopers 304 typically perform one or more operations in order to service request 302. These operations may include supplying data to master 300, invalidating or otherwise updating the coherency state of data cached in one or more L2 caches 110, performing castout operations, writing back data to a system memory 132, etc. If required by request 302, a requested or target memory block may be transmitted to or from master 300 before or after the generation of combined response 310 by response logic 122.

In the following description, the partial response 306 of a snooper 304 to a request 302 and the operations performed by the snooper 304 in response to the request 302 and/or its combined response 310 will be described with reference to whether that snooper is n HPC, an LPC, or neither with respect to the request address specified by the request. In the absence of an HPC for the memory block, the LPC holds the true image of the memory block and has authority to grant or deny requests to generate an additional cached copy of the memory block. For a typical request in the data processing system embodiment of FIGS. 1 and 2, the LPC will be the memory controller 124 for the system memory 132 holding the referenced memory block. Descriptively, the HPC may also provide a copy of the memory block to a requestor in response to an operation that does not modify the memory block. Thus, for a typical request in the data processing system embodiment of FIGS. 1 and 2, the HPC, if any, will be an L2 cache 110. Although other indicators may be utilized to designate an HPC for a memory block, a one embodiment designates the HPC, if any, for a memory block utilizing selected cache coherency state(s) within the L2 cache directory 114 of an L2 cache 110.

Still referring to FIG. 3, the HPC, if any, for a memory block referenced in a request 302, or in the absence of an HPC, the LPC of the memory block, preferably has the responsibility of protecting the transfer of ownership of a memory block, if necessary, in response to a request 302. In the exemplary scenario shown in FIG. 3, a snooper 304 n at the HPC (or in the absence of an HPC, the LPC) for the memory block specified by the request address of request 302 protects the transfer of ownership of the requested memory block to master 300 during a protection window 312 a that extends from the time that snooper 304 n determines its partial response 306 until snooper 304 n receives combined response 310 and during a subsequent window extension 312 b extending a programmable time beyond receipt by snooper 304 n of combined response 310. During protection window 312 a and window extension 312 b, snooper 304 n protects the transfer of ownership by providing partial responses 306 to other requests specifying the same request address that prevent other masters from obtaining ownership (e.g., a retry partial response) until ownership has been successfully transferred to master 300. Master 300 likewise initiates a protection window 313 to protect its ownership of the memory block requested in request 302 following receipt of combined response 310.

Because snoopers 304 all have limited resources for handling the CPU and I/O requests described above, several different levels of partial responses and corresponding CRs are possible. For example, if a snooper 126 within a memory controller 124 that is responsible for a requested memory block has a queue available to handle a request, the snooper 126 may respond with a partial response indicating that it is able to serve as the LPC for the request. If, on the other hand, the snooper 126 has no queue available to handle the request, the snooper 126 may respond with a partial response indicating that it is the LPC for the memory block, but is unable to currently service the request. Similarly, a snooper 116 in an L2 cache 110 may require an available instance of snoop logic and access to L2 cache directory 114 in order to handle a request. Absence of access to either (or both) of these resources results in a partial response (and corresponding CR) signaling an inability to service the request due to absence of a required resource.

Referring now to FIG. 4, there is illustrated a time-space diagram of an exemplary operation flow of an operation of system-wide scope in data processing system 200 of FIG. 2. In these figures, the various processing units 100 within data processing system 200 are tagged with two locational identifiers—a first identifying the processing node (group) 202 to which the processing unit 100 belongs and a second identifying the particular processing unit (chip) 100 within the processing node 202. Thus, for example, processing unit 100 a 0 c refers to processing unit 100 c of processing node 202 a 0. In addition, each processing unit 100 is tagged with a functional identifier indicating its function relative to the other processing units 100 participating in the operation. These functional identifiers include: (1) local master (LM), which designates the processing unit 100 that originates the operation, (2) local hub (LH), which designates a processing unit 100 that is in the same processing node 202 as the local master and that is responsible for transmitting the operation to another processing node 202 (it should be appreciated that a local master can also be a local hub), (3) remote hub (RH), which designates a processing unit 100 that is in a different processing node 202 than the local master and that is responsible to distribute the operation to other processing units 100 in its processing node 202, and (4) remote leaf (RL), which designates a processing unit 100 that is in a different processing node 202 from the local master and that is not a remote hub.

As shown in FIG. 4, the exemplary operation has at least three phases as described above with reference to FIG. 3, namely, a request (or address) phase, a partial response (Presp) phase, and a combined response (Cresp) phase. These three phases preferably occur in the foregoing order and do not overlap. The operation may additionally have a data phase, which may optionally overlap with any of the request, partial response and combined response phases.

Still referring to FIG. 4, the request phase begins when a local master 100 a 0 c (i.e., processing unit 100 c of processing node 202 a 0) performs a synchronized broadcast of a request, for example, a read request, to each of the local hubs 100 a 0 a, 100 a 0 b, 100 a 0 c, and 100 a 0 d within its processing node 202 a 0. It should be noted that the list of local hubs includes local hub 100 a 0 c, which is also the local master. As described further below, this internal transmission is advantageously employed to synchronize the operation of local hub 100 a 0 c with local hubs 100 a 0 a, 100 a 0 b, and 100 a 0 d so that the timing constraints discussed below can be more easily satisfied.

In response to receiving a request, each local hub 100 that is coupled to a remote hub 100 by its A or B links transmits the operation to its remote hub(s) 100. Thus, local hub 100 a 0 a makes no transmission of the operation on its outbound A link, but transmits the operation via its outbound B link to a remote hub within processing node 202 a 1. Local hubs 100 a 0 b, 100 a 0 c, and 100 a 0 d transmit the operation via their respective outbound A and B links to remote hubs in processing nodes 202 b 0 and 202 b 1, processing nodes 202 c 0 and 202 c 1, and processing nodes 202 d 0 and 202 d 1, respectively. Each remote hub 100 receiving the operation in turn transmits the operation to each remote leaf 100 in its processing node 202. Thus, for example, local hub 100 b 0 a transmits the operation to remote leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d. In this manner, the operation is efficiently broadcast to all processing units 100 within data processing system 200 utilizing transmission over no more than three links.

Following the request phase, the partial response (Presp) phase occurs, as shown in FIG. 4. In the partial response phase, each remote leaf 100 evaluates the operation and provides its partial response to the operation to its respective remote hub 100. For example, remote leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d transmit their respective partial responses to remote hub 100 b 0 a. Each remote hub 100 in turn transmits these partial responses, as well as its own partial response, to a respective one of local hubs 100 a 0 a, 100 a 0 b, 100 a 0 c, and 100 a 0 d. Local hubs 100 a 0 a, 100 a 0 b, 100 a 0 c, and 100 a 0 d then broadcast these partial responses, as well as their own partial responses, to each local hub 100 in processing node 202 a 0. It should be noted that the broadcasts of partial responses by the local hubs 100 within processing node 202 a 0 include, for timing reasons, the self-broadcast by each local hub 100 of its own partial response.

As will be appreciated, the collection of partial responses in the manner shown can be implemented in a number of different ways. For example, it is possible to communicate an individual partial response back to each local hub from each other local hub, remote hub, and remote leaf. Alternatively, for greater efficiency, it may be desirable to accumulate partial responses as they are communicated back to the local hubs. In order to ensure that the effect of each partial response is accurately communicated back to local hubs 100, it is preferred that the partial responses be accumulated, if at all, in a non-destructive manner, for example, utilizing a logical OR function and an encoding in which no relevant information is lost when subjected to such a function (e.g., a “one-hot” encoding).

As further shown in FIG. 4, response logic 122 at each local hub 100 within processing node 202 a 0 compiles the partial responses of the other processing units 100 to obtain a combined response representing the system-wide response to the request. Local hubs 100 a 0 a-100 a 0 d then broadcast the combined response to all processing units 100 following the same paths of distribution as employed for the request phase. Thus, the combined response is first broadcast to remote hubs 100, which in turn transmit the combined response to each remote leaf 100 within their respective processing nodes 202. For example, remote hub 100 a 0 b transmits the combined response to remote hub 100 b 0 a, which in turn transmits the combined response to remote leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d.

As noted above, servicing the operation may require an additional data phase. For example, if the operation is a read-type operation, such as a read or RWITM operation, remote leaf 100 b 0 d may source the requested memory block to local master 100 a 0 c via the links connecting remote leaf 100 b 0 d to remote hub 100 b 0 a, remote hub 100 b 0 a to local hub 100 a 0 b, and local hub 100 a 0 b to local master 100 a 0 c. Conversely, if the operation is a write-type operation, for example, a cache castout operation writing a modified memory block back to the system memory 132 of remote leaf 100 b 0 b, the memory block is transmitted via the links connecting local master 100 a 0 c to local hub 100 a 0 b, local hub 100 a 0 b to remote hub 100 b 0 a, and remote hub 100 b 0 a to remote leaf 100 b 0 b.

Referring now to FIG. 5, there is illustrated a time-space diagram of an exemplary operation flow of an operation of group scope in data processing system 200 of FIG. 2. In these figures, the various processing units 100 within data processing system 200 are tagged with two locational identifiers—a first identifying the processing node (group) 202 to which the processing unit 100 belongs and a second identifying the particular processing unit 100 within the processing node (group) 202. Thus, for example, processing unit 100 b 0 a refers to processing unit 100 a of processing node 202 b 0. In addition, each processing unit 100 is tagged with a functional identifier indicating its function relative to the other processing units 100 participating in the operation. These functional identifiers include: (1) node master (NM), which designates the processing unit 100 that originates an operation of node-only (group) scope, and (2) node leaf (NL), which designates a processing unit 100 that is in the same processing node 202 as the node master and that is not the node (group) master.

As shown in FIG. 5, the exemplary group operation has at least three phases as described above: a request (or address) phase, a partial response (Presp) phase, and a combined response (Cresp) phase. Again, these three phases preferably occur in the foregoing order and do not overlap. The operation may additionally have a data phase, which may optionally overlap with any of the request, partial response and combined response phases.

Still referring to FIG. 5, the request phase begins when a node master 100 b 0 a (i.e., processing unit 100 a of processing node 202 b 0), which functions much like a remote hub in the operational scenario of FIG. 5, performs a synchronized broadcast of a request, for example, a read request, to each of the node leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d within its processing node 202 b 0. It should be noted that, because the scope of the broadcast transmission is limited to a single node, no internal transmission of the request within node master 100 b 0 a is employed to synchronize off-node transmission of the request.

Following the request phase, the partial response (Presp) phase occurs, as shown in FIG. 5. In the partial response phase, each of node leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d evaluates the operation and provides its partial response to the operation to node master 100 b 0 a. Next, as further shown in FIG. 5, response logic 122 at node master 100 b 0 a within processing node 202 b 0 compiles the partial responses of the other processing units 100 to obtain a combined response representing the node-wide response to the request. Node master 100 b 0 a then broadcasts the combined response to all node leaves 100 b 0 b, 100 b 0 c, and 100 b 0 d utilizing the X, Y and Z links of node master 100 b 0 a.

As noted above, servicing the operation may require an additional data phase. For example, if the operation is a read-type operation, such as a read or RWITM operation, node leaf 100 b 0 d may source the requested memory block to node master 100 b 0 a via the Z link connecting node leaf 100 b 0 d to node master 100 b 0 a. Conversely, if the operation is a write-type operation, for example, a cache castout operation writing a modified memory block back to the system memory 132 of remote leaf 100 b 0 b, the memory block is transmitted via the X link connecting node master 100 b 0 a to node leaf 100 b 0 b.

As described above with reference to FIG. 3, coherency is maintained during the “handoff” of coherency ownership of a memory block from a snooper 304 n to a requesting master 300 in the possible presence of other masters competing for ownership of the same memory block through protection window 312 a, window extension 312 b, and protection window 313. For example, as shown in FIG. 6, protection window 312 a and window extension 312 b must together be of sufficient duration to protect the transfer of coherency ownership of the requested memory block from snooper 304 n to winning master (WM) 300 in the presence of a competing request 322 by a competing master (CM) 320. To ensure that protection window 312 a and window extension 312 b have sufficient duration to protect the transfer of ownership of the requested memory block from snooper 304 n to winning master 300, the latency of communication between processing units 100 in accordance with FIGS. 4 and 5 is preferably constrained such that the following conditions are met:

A_lat(CM_S)≤A_lat(CM_WM)+C_lat(WM_S)+ε,

where A_lat(CM_S) is the address latency of any competing master (CM) 320 to the snooper (S) 304 n owning coherence of the requested memory block, A_lat(CM_WM) is the address latency of any competing master (CM) 320 to the “winning” master (WM) 300 that is awarded coherency ownership by snooper 304 n, C_lat(WM_S) is the combined response latency from the time that the combined response is received by the winning master (WM) 300 to the time the combined response is received by the snooper (S) 304 n owning the requested memory block, and c is the duration of window extension 312 b.

If the foregoing timing constraint, which is applicable to a system of arbitrary topology, is not satisfied, the request 322 of the competing master 320 may be received (1) by winning master 300 prior to winning master 300 assuming coherency ownership and initiating protection window 312 b and (2) by snooper 304 n after protection window 312 a and window extension 312 b end. In such cases, neither winning master 300 nor snooper 304 n will provide a partial response to competing request 322 that prevents competing master 320 from assuming coherency ownership of the memory block and reading non-coherent data from memory. However, to avoid this coherency error, window extension 312 b can be programmably set (e.g., by appropriate setting of configuration register 123) to an arbitrary length epsilon (c) to compensate for latency variations or the shortcomings of a physical implementation that may otherwise fail to satisfy the timing constraint that must be satisfied to maintain coherency. Thus, by solving the above equation for ε, the ideal length of window extension 312 b for any implementation can be determined. For the data processing system embodiments of FIG. 2, it is preferred if ε has a duration equal to the latency of one first tier link chip-hop for broadcast operations having a scope including multiple processing nodes 202 and has a duration of zero for operations of group scope.

Several observations may be made regarding the foregoing timing constraint. First, the address latency from the competing master 320 to the owning snooper 304 a has no necessary lower bound, but must have an upper bound. The upper bound is designed for by determining the worst case latency attainable given, among other things, the maximum possible oscillator drift, the longest links coupling processing units 100, the maximum number of accumulated stalls, and guaranteed worst case throughput. In order to ensure the upper bound is observed, the interconnect fabric must ensure non-blocking behavior.

Second, the address latency from the competing master 320 to the winning master 300 has no necessary upper bound, but must have a lower bound. The lower bound is determined by the best case latency attainable, given, among other things, the absence of stalls, the shortest possible link between processing units 100 and the slowest oscillator drift given a particular static configuration.

Although for a given operation, each of the winning master 300 and competing master 320 has only one timing bound for its respective request, it will be appreciated that during the course of operation any processing unit 100 may be a winning master for some operations and a competing (and losing) master for other operations. Consequently, each processing unit 100 effectively has an upper bound and a lower bound for its address latency.

Third, the combined response latency from the time that the combined response is generated to the time the combined response is observed by the winning master 300 has no necessary lower bound (the combined response may arrive at the winning master 300 at an arbitrarily early time), but must have an upper bound. By contrast, the combined response latency from the time that a combined response is generated until the combined response is received by the snooper 304 n has a lower bound, but no necessary upper bound (although one may be arbitrarily imposed to limit the number of operations concurrently in flight).

Fourth, there is no constraint on partial response latency. That is, because all of the terms of the timing constraint enumerated above pertain to request/address latency and combined response latency, the partial response latencies of snoopers 304 and competing master 320 to winning master 300 have no necessary upper or lower bounds.

The first tier and second tier links connecting processing units 100 may be implemented in a variety of ways to obtain the topologies depicted in FIG. 2 and to meet the timing constraints illustrated in FIG. 6. In one preferred embodiment, each inbound and outbound first tier (X, Y and Z) link and each inbound and outbound second tier (A and B) link is implemented as a uni-directional 8-byte bus containing a number of different virtual channels or tenures to convey address, data, control and coherency information.

FIG. 7 illustrates an exemplary embodiment of a write request partial response 720, which may be transported within either a local partial response field 708 a, 708 b or a remote partial response field 712 a, 712 b in response to a write request. As shown, write request partial response 720 is two bytes in length and includes a 15-bit destination tag field 724 for specifying the tag of a snooper (e.g., an IMC snooper 126) that is the destination for write data and a 1-bit valid (V) flag 722 for indicating the validity of destination tag field 724.

Referring now to FIG. 8, there is depicted a block diagram illustrating request logic 121 a within interconnect logic 120 of FIG. 1 utilized in request phase processing of an operation. As shown, request logic 121 a includes a master multiplexer 900 coupled to receive requests by the masters 300 of a processing unit 100 (e.g., masters 112 within L2 cache 110 and masters within I/O controller 128). The output of master multiplexer 900 forms one input of a request multiplexer 904. The second input of request multiplexer 904 is coupled to the output of a remote hub multiplexer 903 having its inputs coupled to the outputs of hold buffers 902 a, 902 b, which are in turn coupled to receive and buffer requests on the inbound A and B links, respectively. Remote hub multiplexer 903 implements a fair allocation policy, described further below, that fairly selects among the requests received from the inbound A and B links that are buffered in hold buffers 902 a-902 b. If present, a request presented to request multiplexer 904 by remote hub multiplexer 903 is always given priority by request multiplexer 904. The output of request multiplexer 904 drives a request bus 905 that is coupled to each of the outbound X, Y, and Z links, a node master/remote hub (NM/RH) hold buffer 906, and the local hub (LH) address launch buffer 910. A previous request FIFO buffer 907, which is also coupled to request bus 905, preferably holds a small amount of address-related information for each of a number of previous address tenures to permit a determination of the address slice or resource bank 1412 to which the address, if any, communicated in that address tenure hashes. For example, in one embodiment, each entry of previous request FIFO buffer 907 contains a “1-hot” encoding identifying a particular one of banks 1412 a-1412 n to which the request address of an associated request hashed. For address tenures in which no request is transmitted on request bus 905, the 1-hot encoding would be all ‘0’s.

The inbound first tier (X, Y, and Z) links are each coupled to the LH address launch buffer 910, as well as a respective one of node leaf/remote leaf (NL/RL) hold buffers 914 a-914 c. The outputs of NM/RH hold buffer 906, LH address launch buffer 910, and NL/RL hold buffers 914 a-914 c all form inputs of a snoop multiplexer 920. Coupled to the output of LH address launch buffer 910 is another previous buffer 911, which is preferably constructed like previous request FIFO buffer 907. The output of snoop multiplexer 920 drives a snoop bus 922 to which tag FIFO queues 924, the snoopers 304 (e.g., snoopers 116 of L2 cache 110 and snoopers 126 of IMC 124) of the processing unit 100, and the outbound A and B links are coupled. Snoopers 304 are further coupled to and supported by local hub (LH) partial response FIFO queues 930 and node master/remote hub (NM/RH) partial response FIFO queue 940.

In one or more embodiments buffers 902, 906, and 914 a-914 c are relatively small in order to minimize communication latency. In one embodiment, each of buffers 902, 906, and 914 a-914 c is sized to hold only the address tenure(s) of a single frame of the selected link information allocation.

With reference now to FIG. 9, there is illustrated a more detailed block diagram of local hub (LH) address launch buffer 910 of FIG. 8. As depicted, the local and inbound X, Y, and Z link inputs of the LH address launch buffer 910 form inputs of a map logic 1010, which places requests received on each particular input into a respective corresponding position-dependent FIFO queue 1020 a-1020 d. In the depicted nomenclature, the processing unit 100 a in the upper left-hand corner of a processing node/MCM 202 is the “S” chip; the processing unit 100 b in the upper right-hand corner of the processing node/MCM 202 is the “T” chip; the processing unit 100 c in the lower left-hand corner of a processing node/MCM 202 is the “U” chip; and the processing unit 100 d in the lower right-hand corner of the processing node 202 is the “V” chip. Thus, for example, for local master/local hub 100 ac, requests received on the local input are placed by map logic 1010 in U FIFO queue 1020 c, and requests received on the inbound Y link are placed by map logic 1010 in S FIFO queue 1020 a. Map logic 1010 is employed to normalize input flows so that arbitration logic 1032, described below, in all local hubs 100 is synchronized to handle requests identically without employing any explicit inter-communication.

The outputs of position-dependent FIFO queues 1020 a-1020 d form the inputs of local hub request multiplexer 1030, which selects one request from among position-dependent FIFO queues 1020 a-1020 d for presentation to snoop multiplexer 920 in response to a select signal generated by arbiter 1032. Arbiter 1032 implements a fair arbitration policy that is synchronized in its selections with the arbiters 1032 of all other local hubs 100 within a given processing node 202 so that the same request is broadcast on the outbound A links at the same time by all local hubs 100 in a processing node 202. In one or more embodiments, commands are issued at a certain link rate. If a dispatch rate out of position-dependent FIFO queues 1020 a-1020 d falls behind the incoming rate, commands are dropped by arbiter 1032.

Referring now to FIG. 10, there is depicted a more detailed block diagram of tag FIFO queues 924 of FIG. 8. As shown, tag FIFO queues 924 include a local hub (LH) tag FIFO queue 924 a, remote hub (RH) tag FIFO queues 924 b 0-924 b 1, node master (NM) tag FIFO queue 924 b 2, remote leaf (RL) tag FIFO queues 924 c 0-924 c 1, 924 d 0-924 d 1 and 924 e 0-924 e 1, and node leaf (NL) tag FIFO queues 924 c 2, 924 d 2 and 924 e 2. The master tag of a request of an operation of system-wide scope is deposited in each of tag FIFO queues 924 a, 924 b 0-924 b 1, 924 c 0-924 c 1, 924 d 0-924 d 1 and 924 e 0-924 e 1 when the request is received at the processing unit(s) 100 serving in each of these given roles (LH, RH, and RL) for that particular request. Similarly, the master tag of a request of an operation of node-only scope is deposited in each of tag FIFO queues 924 b 2, 924 c 2, 924 d 2 and 924 e 2 when the request is received at the processing unit(s) 100 serving in each of these given roles (NM and NL) for that particular request. The master tag is retrieved from each of tag FIFO queues 924 when the combined response is received at the associated processing unit 100. Thus, rather than transporting the master tag with the combined response, master tags are retrieved by a processing unit 100 from its tag FIFO queue 924 as needed, resulting in bandwidth savings on the first and second tier links. Given that the order in which a combined response is received at the various processing units 100 is identical to the order in which the associated request was received, a FIFO policy for allocation and retrieval of the master tag can advantageously be employed.

LH tag FIFO queue 924 a includes a number of entries, each including a master tag field 1100 for storing the master tag of a request launched by arbiter 1032. Each of tag FIFO queues 924 b 0-924 b 1 similarly includes multiple entries, each including at least a master tag field 1100 for storing the master tag of a request of system-wide scope received by a remote hub 100 via a respective one of the inbound A and B links. Tag FIFO queues 924 c 0-924 c 1, 924 d 0-924 d 1 and 924 e 0-924 e 1 are similarly constructed and each hold master tags of requests of system-wide scope received by a remote leaf 100 via a unique pairing of inbound first and second tier links. For requests of node-only broadcast scope, NM tag FIFO queues 924 b 2 holds the master tags of requests originated by the node master 100, and each of NL tag FIFO queues 924 c 2, 924 d 2 and 924 e 2 provides storage for the master tags of requests received by a node leaf 100 on a respective one of the first tier X, Y, and Z links.

Entries within LH tag FIFO queue 924 a have the longest tenures for system-wide broadcast operations, and NM tag FIFO queue 924 b 2 have the longest tenures for node-only broadcast operations. Consequently, the depths of LH tag FIFO queue 924 a and NM tag FIFO queue 924 b 2 respectively limit the number of concurrent operations of system-wide scope that a processing node 202 can issue on the interconnect fabric and the number of concurrent operations of node-only scope that a given processing unit 100 can issue on the interconnect fabric. These depths have no necessary relationship and may be different. However, the depths of tag FIFO queues 924 b 0-924 b 1, 924 c 0-924 c 1, 924 d 0-924 d 1 and 924 e 0-924 e 1 are preferably designed to be equal to that of LH tag FIFO queue 924 a, and the depths of tag FIFO queues 924 c 2, 924 d 2 and 924 e 2 are preferably designed to be equal to that of NM tag FIFO queue 924 b 2.

With reference now to FIGS. 11 and 12, there are illustrated more detailed block diagrams of exemplary embodiments of the local hub (LH) partial response FIFO queue 930 and node master/remote hub (NM/RH) partial response FIFO queue 940 of FIG. 8. As indicated, LH partial response FIFO queue 930 includes a number of entries 1200 that each includes a partial response field 1202 for storing an accumulated partial response for a request and a response flag array 1204 having respective flags for each of the 6 possible sources from which the local hub 100 may receive a partial response (i.e., local (L), first tier X, Y, Z links, and second tier A and B links) at different times or possibly simultaneously. Entries 1200 within LH partial response FIFO queue 930 are allocated via an allocation pointer 1210 and deallocated via a deallocation pointer 1212. Various flags comprising response flag array 1204 are accessed utilizing A pointer 1214, B pointer 1215, X pointer 1216, Y pointer 1218, and Z pointer 1220.

As described further below, when a partial response for a particular request is received by partial response logic 121 b at a local hub 100, the partial response is accumulated within partial response field 1202, and the link from which the partial response was received is recorded by setting the corresponding flag within response flag array 1204. The corresponding one of pointers 1214, 1215, 1216, 1218 and 1220 is then advanced to the subsequent entry 1200.

Of course, as described above, each processing unit 100 need not be fully coupled to other processing units 100 by each of its 5 inbound (X, Y, Z, A and B) links. Accordingly, flags within response flag array 1204 that are associated with unconnected links are ignored. The unconnected links, if any, of each processing unit 100 may be indicated, for example, by the configuration indicated in configuration register 123, which may be set, for example, by boot code at system startup or by the operating system when partitioning data processing system 200.

As can be seen by comparison of FIG. 12 and FIG. 11, NM/RH partial response FIFO queue 940 is constructed similarly to LH partial response FIFO queue 930. NM/RH partial response FIFO queue 940 includes a number of entries 1230 that each includes a partial response field 1202 for storing an accumulated partial response and a response flag array 1234 having respective flags for each of the up to 4 possible sources from which the node master or remote hub 100 may receive a partial response (i.e., node master (NM)/remote (R), and first tier X, Y, and Z links). In addition, each entry 1230 includes a route field 1236 identifying whether the operation is a node-only, group, or system-wide broadcast operation and, for system-wide broadcast operations, which of the inbound second tier links the request was received upon (and thus which of the outbound second tier links the accumulated partial response will be transmitted on). Entries 1230 within NM/RH partial response FIFO queue 940 are allocated via an allocation pointer 1210 and deallocated via a deallocation pointer 1212. Various flags comprising response flag array 1234 are accessed and updated utilizing X pointer 1216, Y pointer 1218, and Z pointer 1220.

As noted above with respect to FIG. 11, each processing unit 100 need not be fully coupled to other processing units 100 by each of its first tier X, Y, and Z links. Accordingly, flags within response flag array 1204 that are associated with unconnected links are ignored. The unconnected links, if any, of each processing unit 100 may be indicated, for example, by the configuration indicated in configuration register 123.

With reference now to FIG. 13, there is illustrated a high level logical flowchart of an exemplary process 1300 implemented by a master of a cache (e.g., master 112 of L2 cache 110). In block 1302 process 1300 is initiated, e.g., in response to a transaction being received by L2 cache 110. Next, in decision block 1304, an assigned master 112 determines whether the received transaction corresponds to L2 cache 110 obtaining ownership of a cache line, e.g., via cache intervention. In response to L2 cache 110 not obtaining ownership of a cache line (and not becoming HPC for the cache line) in block 1304 control transfers to block 1316, where process 1300 terminates. In response to L2 cache 110 obtaining ownership of a cache line (and becoming HPC for the cache line) in block 1304 control transfers to decision block 1308.

In block 1308 master 112 determines whether L2 cache 110 holds the cache line in a required state. For example, the required state may correspond to a modified state or an invalidated state. In response to L2 cache 110 not holding the cache line in the required state in block 1308 control transfers to block 1316. In response to L2 cache 110 holding the cache line in the required state in block 1308 control transfers to decision block 1310. In block 1310 master 112 determines whether one or more data segments are needed for the cache line. In response to L2 cache 110 having all desired data segments for the cache line in block 1310 control transfers to block 1316.

In response to L2 cache 110 not having all desired data segments for the cache line in block 1310 control transfers to block 1312, where master 112 issues a command (i.e., an hpc_read command) to one or more LPCs (e.g., IMCs 124), as dependent on the scope of the command and the topology of data processing system 200, requesting the desired data segment(s). Next, in decision block 1314, master 112 determines whether L2 cache 110 has received the requested data or has received a retry response (e.g., indicating an LPC associated with the address is busy). In response to receiving a retry response in block 1314 control returns to block 1312, where master 112 issues another hpc_read command to the one or more LPCs. In response to L2 cache 110 receiving the requested data in block 1314 control transfers to block 1316.

While the invention has been particularly shown as described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. For example, although the present invention discloses embodiments in which FIFO queues are utilized to order operation-related tags and partial responses, those skilled in the art will appreciated that other ordered data structures may be employed to maintain an order between the various tags and partial responses of operations. In addition, although embodiments of the present disclosure employ uni-directional communication links, those skilled in the art will understand by reference to the foregoing that bi-directional communication links could alternatively be employed. Moreover, although embodiments have been described with reference to specific exemplary interconnect fabric topologies, the present invention is not limited to those specifically described herein and is instead broadly applicable to a number of different interconnect fabric topologies.

In the flow charts, the methods depicted in the figures may be embodied in a computer-readable medium as one or more design files. In some implementations, certain steps of the methods may be combined, performed simultaneously or in a different order, or perhaps omitted, without deviating from the spirit and scope of the invention. Thus, while the method steps are described and illustrated in a particular sequence, use of a specific sequence of steps is not meant to imply any limitations on the invention. Changes may be made with regards to the sequence of steps without departing from the spirit or scope of the present invention. Use of a particular sequence is therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the appended claims.

As will be appreciated by one skilled in the art, aspects of the present invention may be embodied as a system, method, or computer program product. Accordingly, aspects of the present invention may take the form of an entirely hardware embodiment or an embodiment combining software and hardware aspects that may all generally be referred to herein as a “circuit,” “module” or “system.”

Any combination of one or more computer-readable medium(s) may be utilized. The computer-readable medium may be a computer-readable signal medium or a computer-readable storage medium. A computer-readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any suitable combination of the foregoing, but does not include a computer-readable signal medium. More specific examples (a non-exhaustive list) of the computer-readable storage medium would include the following: a portable computer diskette, a hard disk, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or Flash memory), a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing. In the context of this document, a computer-readable storage medium may be any tangible storage medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device.

While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular system, device or component thereof to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims. Moreover, the use of the terms first, second, etc. do not denote any order or importance, but rather the terms first, second, etc. are used to distinguish one element from another.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

The corresponding structures, materials, acts, and equivalents of all means or step plus function elements in the claims below, if any, are intended to include any structure, material, or act for performing the function in combination with other claimed elements as specifically claimed. The description of the present invention has been presented for purposes of illustration and description, but is not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the invention. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated. 

What is claimed is:
 1. A method of operating a data processing system, comprising: transitioning, by a cache, to a highest point of coherency (HPC) for a cache line in a required state without receiving data for one or more segments of the cache line that are needed; issuing, by the cache, a command to a lowest point of coherency (LPC) that requests data for the one or more segments of the cache line that were not received and are needed; and receiving, by the cache, the data for the one or more segments of the cache line from the LPC that were not previously received and were needed.
 2. The method of claim 1, wherein the LPC corresponds to a memory controller whose address is specified in the command and the required state is a modified state.
 3. The method of claim 1, wherein the cache is a level two (L2) cache in the data processing system.
 4. The method of claim 1, wherein the cache obtains ownership of the cache line through intervention from another cache.
 5. The method of claim 1, wherein the command is given priority over any other access to the cache line.
 6. The method of claim 1, wherein the command is not snooped by snoopers of any L2 cache in the data processing system.
 7. The method of claim 1, wherein the LPC is a memory controller having an address specified by the command.
 8. A data processing system, comprising: a memory; and a processing unit coupled to the memory, wherein the processing unit includes a cache that is configured to: transition to a highest point of coherency (HPC) for a cache line in a required state without receiving data for one or more segments of the cache line that are needed; issue a command to a lowest point of coherency (LPC) requesting data for the one or more segments of the cache line that were not received and are needed; and receive the data for the one or more segments of the cache line from the LPC that were not previously received and were needed.
 9. The data processing system of claim 8, wherein the LPC corresponds to a memory controller whose address is specified in the command and the required state is a modified state.
 10. The data processing system of claim 8, wherein the cache is a level 2 (L2) cache that includes a master that issues the command.
 11. The data processing system of claim 8, wherein the cache obtains ownership of the cache line through intervention from another cache.
 12. The data processing system of claim 8, wherein the command is given priority over any other access to the cache line.
 13. The data processing system of claim 8, wherein the command is not snooped by snoopers of any level 2 (L2) cache in the data processing system.
 14. The data processing system of claim 8, wherein the LPC is a memory controller having an address specified by the command.
 15. A processing unit, comprising: a processing core including a level one (L1) cache; and a lower level cache coupled to the processing core, wherein the lower level cache is configured to: transition to a highest point of coherency (HPC) for a cache line in a required state without receiving data for one or more segments of the cache line that are needed; issue a command to a lowest point of coherency (LPC) requesting data for the one or more segments of the cache line that were not received and are needed; and receive the data for the one or more segments of the cache line from the LPC that were not previously received and were needed.
 16. The processing unit of claim 15, wherein the LPC corresponds to a memory controller whose address is specified in the command and the required state is a modified state.
 17. The processing unit of claim 15, wherein the lower level cache is a level two (L2) cache that includes a master that issues the command.
 18. The processing unit of claim 15, wherein the lower level cache obtains ownership of the cache line through intervention from another cache.
 19. The processing unit of claim 15, wherein the command is given priority by the LPC over any other access to the cache line.
 20. The processing unit of claim 15, wherein the LPC is a memory controller having an address specified by the command. 